nanotechnology in medical research: whh dh?here, when and …to accurate diagnosis including...
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Nanotechnology in medical research:h h d h ?where, when and why?
Marc BaumannProtein Chemistry/Proteomics Unit
and the Neuroscience Programand the Neuroscience ProgramBiomedicum Helsinki
E M il b @h l i ki fiE-Mail: [email protected]
(http://research.med.helsinki.fi/corefacilities/proteinchem)
MAJOR BIOLOGICAL MACROMOLECULES IN NANOSCALE
What are the major biological macromolecules inNANOSCALE?
MAJOR BIOLOGICAL MACROMOLECULES IN NANOSCALE
What are the major biological macromolecules inNANOSCALE?
Philosophical question with no answer!!
Every biomolecule is in nanoscale and all they are equally important…
Nanomedicine what is all about?Nanomedicine, what is all about?
Nanomedicine what is all about?Nanomedicine, what is all about?
Our dream!
19991999(J. Lertola)
Medical microchips' massive potential
2mm
Robotic techniques could revolutionize heart surgery q g y
Nanomedicine
Nanomedicine may be defined as the monitoring, repair, constructionand control of human biological systems at the molecular level, usingengineered nanodevices and nanostructures.
Nanotechnology Thorough, inexpensive control of the structure ofNanotechnology Thorough, inexpensive control of the structure ofmatter based on molecule-by-molecule control of products andbyproducts; the products and processes of molecular manufacturing,incl ding molec lar machinerincluding molecular machinery.
Nanomedicine cont…
N A i t i l di l l i d llNanosurgery A generic term including molecular repair and cell surgery.
Nanodentistry The maintenance of comprehensive oral health by employingnanomaterials biotechnology including tissue engineering and dental nanoroboticsnanomaterials, biotechnology including tissue engineering and dental nanorobotics.
Bio-nanomaterial science Materials which are in direct contact with biological fluidsor living tissue, with minimal adverse reaction or rejection by the body.or living tissue, with minimal adverse reaction or rejection by the body.
Nanomachine An artificial molecular machine of the sort made by molecularmanufacturing.g
(Nano-: A prefix meaning one billionth (1/1,000,000,000).)
For what do you think medicineFor what do you think medicine could use nanotechnology?
What do you think medicine couldWhat do you think medicine could use nanotechnology for?
BiomaterialsBoneTeethTeethCellsCartilageI tImmune systemViral and bacterial attackDrug deliveryDiagnostics
Bionanomaterials1) orthopedic prostheses such as total knee and hip joint replacements, spinal implants, bonefixators, and tendon and ligament prostheses;
2) cardiovascular implants such as artificial heart valves, vascular grafts and stents, pacemakers,and implantable defibrillators;and implantable defibrillators;
3) neural implants (e.g., cochlear implants) and cerebrospinal fluid drainage systems (e.g.,hydrocephalus shunts);
4) plastic and reconstructive implants such as breast augmentation or reconstruction,maxillofacial reconstruction, artificial larynx, penile implants, and injectable collagen for softtissue augmentation;tissue augmentation;
5) dental implants to replace teeth/root systems and bony tissue in the oral cavity;
6) hth l i t i l di t t d i t l l6) ophthalmic systems including contact and intraocular lenses;
7) catheters and bladder stimulators;
8) drug-dispensing implants such as insulin pumps;
9) general surgical systems such as sutures, staples, adhesives, and blood substitutes.
Stent and Catheter Developments• Biodegradeable, Drug-Eluting Stents (DES)g , g g ( )• BioMEMS sensor stents and catheters
Stentenna – transmits blood flow and pressure dataCourtesy U. of MichiganCourtesy U. of Michigan
BioMEMS Catheter Technology
Bioactive materials
1) Chemically inert materials (e.g. Titanium, tantalum, polyethylene, alumina)
>> Are not inert but get a fiborous tissue capsule around them
2) Bioresorbable materials (e.g. tricalcium phosphate, polylacti-polyclycolic acid) ( g p p , p y p y ycopolymers)
>> Used as drug delivery applications, biodegradable implants (sutures, stents,screws etc.)
Here we will see the nanofibres come up!! (Star Inc. Electrospun nanofibers;S i T h N fib f i d bi l i l l )(150 fib )eSpin Tech. Nanofibers of organic and biological polymers)(150nm fibers).
3) Bioactive materials (e.g. Glass, ceramics, glass-ceramics, plasma-sprayedHydroxyapatide oxidized silicon sodium calcium phosphorus etc )Hydroxyapatide, oxidized silicon, sodium, calcium, phosphorus etc.)
Bioactive materials cont...
The goals is to alter the surface material by changing the atomic structure and chemistrye.g. Ceramic is not very bioactive but when treated with Ion beam surface modificatione.g. Ceramic is not very bioactive but when treated with Ion beam surface modificationit become bioactive.
Cells align themselves to nano-scale features on a titanium surface, and the size andg ,shape of features can control the behavior of different cells.
For instance, fibroblasts (responsible for new collagen fiber deposition during woundhealing) migrate along the nano-sized grooves, while macrophages (white bloodcells responsible for digesting foreign matter) can become trapped within thesefeatures. Biomaterial scientists can exploit such topographical controls to provide
t id ti d h linew ways to guide regeneration and healing.
Orthopedic biomaterialsArtificial joints consist of a plastic cup made of ultrahigh molecular weightpolyethylene, placed in the joint socket, and a metal (titanium or cobalt chromiumalloy) or ceramic (aluminum oxide or zirconium oxide) ball affixed to a metal stem.
Billion of tiny polymer particles are shed into the surrounding synovial fluid andtissues during the life time of the AJ (8-12 Years).
>> Inflammatory cells lack receptors for ultrahigh density polyethylene or fragments>> Inflammatory cells lack receptors for ultrahigh-density polyethylene or fragmentsthereof, yet are able to recognize these utterly foreign objects as such and attack them.
Left: intervertebral disc, 12 months after treatment with autologous disc chondrocytes
Right: untreated intervertebral discgRegenerated discs mimic native disc morphology;autologous treatment promotes tissue regeneration.
Fibroblast cell on a nanostructured surface
Note: that in many nanomedical applications, tissue integration with theimplant is desirable!! For other applications such as hemodynamic systems,p pp y y ,a nonadhesive inert nanodevice surface is desirable!!
Nanotechnology in medical research:h h d h ?where, when and why?
The European way:The European way:
European TechnologyPlatform on NanoMedicine NanomedicinePlatform on NanoMedicineNanotechnology for Health
Vision Paperand Basis for a Strategic Research Agendafor NanoMedicine
NanomedicineN a n o t e c h n o l o g y f o r H e a l t h
September 2005
November 2006
EUROPEAN COMISSION
European TechnologyPlatform on NanoMedicinePlatform on NanoMedicineNanotechnology for Health
Vision Paperand Basis for a Strategic Research Agendafor NanoMedicine
September 2005
European TechnologyPlatform on NanoMedicinePlatform on NanoMedicineNanotechnology for Health
Vision Paperand Basis for a Strategic Research Agendafor NanoMedicine
September 2005
Nanomedical developments range fromnanoparticles for molecular diagnostics imagingnanoparticles for molecular diagnostics, imagingand therapy to integrated medical nanosystems,which may perform complex repair actions at thecellular level inside the body in the future.cellular level inside the body in the future.
EUROPEAN SCIENCE FOUNDATION
The field of ‘Nanomedicine’ is the science andt h l f di i t ti dtechnology of diagnosing, treating andpreventing disease and traumatic injury, ofrelieving pain, and of preserving and improvinghuman health using molecular tools and Nanomedicinehuman health, using molecular tools andmolecular knowledge of the human body. It wasperceived as embracing five main sub-disciplinesthat in many ways are overlapping and
NanomedicineN a n o t e c h n o l o g y f o r H e a l t h
that in many ways are overlapping andunderpinned by the following commontechnical issues.
Analytical Tools• Nanoimaging• Nanomaterials and Nanodevices
N l Th ti d D D li S t
November 2006
• Novel Therapeutics and Drug Delivery Systems• Clinical, Regulatory and Toxicological Issues
EUROPEAN SCIENCE FOUNDATION
EUROPEAN SCIENCE FOUNDATION
DNA hi l b hi t b l t h i l d t tiDNA chips lab on chip nanotubes electrochemical detection
protein-chips pill on chip nanowires optical detection
glyco-chips nanofluidics nanoparticles mechanical detection
cell-chips nanostructured surfaces electrical detection - bycell chips nanostructured surfaces electrical detection by scanning probes - by mass spectrometry - by electronmicroscopy
biosensors for single and multiple analytes
nanodevices and nanoelectronicsand multiple analytes nanoelectronics
What do we have
• Fast Minimise consultation time (<1 minute)
• Simple Lay person (nurse’s aid) can use What do we want• Portable Take the test to the patient
• Storage Room temperature for consumables
• Painless Minimally invasive blood sampling
What do we want
Geneticdisposition
DNAMutations
Today
Future
• Specific • Molecular • Mini-invasive • MI, MDx
markers imaging: surgery • Non-invasive,
(MDx) quantitative, • Local/target- Quantitative
whole-body ed drug imaging
• CA Diagnosis delivery & CA Diagnosis delivery &
tracing
• Tissue analy-
sis (MDx)
Drug delivery and Pharmaceutical development
At the Doctors Office
Examination and Diagnosis of a Patient
The first step in any treatment process is the examination of the patient,including the individual's medical history, personal functional andstructural baseline and current complaintsstructural baseline, and current complaints.
Advancing technology has also brought a plethora of tests that contributeto accurate diagnosis including auscultation microscopy and clinicalto accurate diagnosis, including auscultation, microscopy and clinicalbacteriology in the 19th century, and radiological scanning, clinicalbiochemistry, genetic testing, and minimally invasive exploratorysurgery in the 20th centurysurgery in the 20th century.
In the 21st century, new tools for nanomedical testing and observationwill include clinical in vivo cytography; real-time whole-bodywill include clinical in vivo cytography; real time whole bodymicrobiotic surveys; immediate access to laboratory-quality data onthe patient.
An Example
A patient presents in the clinic with mild fever, nasal congestion,di f t d h A b f hi th t i t kdiscomfort, and cough. A swab of his throat is taken.
What do we do now?
The sample is analyzed by recombinant DNA techniques.The cotton throat swab is mixed with a cocktail of DNA probes.
(In approx 24 hours we will have the first answers for the pathogen!)(In approx. 24 hours we will have the first answers for the pathogen!)
What do we do in the future?
The physician faces the patient and pulls from his pocket a lightweight
MD (Molecular Diagnostics) Chip for Preventive & Personalized Medicine
handheld device resembling a pocket calculator…
Di bl Di i Bi hi
Nature Biotechnology 22, 6 - 7 (2004)
Biomedical analysis & communication system
Disposable Diagnostic Biochip
Prof. Luke P. Lee, Berkelyy
NanoInfo Bio
In-vivo IR Spectroscopy
Confocal microscopy
Cell trapping
microscopy
Confocal nSERS
In-vivo detectionwindow μCIAs
Cell lysing nSERS
Cellular Analysis
1mmCell sorting
Nanogap Junction
Lab Automation: Sample Prep, SMM, & SMD
Microfluidic Pumps
Cell sorting by
adhesion proteinMicrofluidic interface
Nanomedicine
The physician faces the patient and pulls from his pocket a lightweight handheld device resembling a pocket calculator…lightweight handheld device resembling a pocket calculator…
Self-sterilizing cordless pencil-sized probe
Acoustic echolocation transceivers
Probe tip result Screen
Result in a few seconds
Probe tip contains billions of nanoscale molecular assay receptors
Solid State Ultrasound
cMUT MEMS ArrayCapacitive micro-fabricated
• Enabling Technologies• Integration
ultrasonic transducers
• Benefits• Portable applications
Integration– MEMS transducer and
electronics in the same miniature circuit pp
• Flexible sheet-like “probe”• Low-cost manufacturing
• Miniaturization– Highest density, performance
interconnect & packaging
Th di i i l t d i f d th i f ti t iThe diagnosis is completed in a few seconds, the infectious agent isPromptly Exterminated and a resurvey with the probe several minutesafterwards reveals no evidence of the pathogen.
Key words:
- Diagnostic- TreatmentTreatment
Quantum Dot Applications in Cancer Management
Quantum dots Laboratory diagnosticsProtein binding & internalization
Q d l b lli Sentinel node visualization for breast cancer
through 1 cm of tissue
Quantum dot labelling of mouse colon cancer
Intra-Operative ImagingSentinal lymph node evaluation and tumour extent y p
99mTc99mTc NanoColloid
Zentralklinikum Augsburg, Nuklearmedizin
Quantum Dot Nanoparticle Fluorescence
Nanomedicine will offer in the doctors office…
- in-office comprehensive genotyping
- real-time whole-body scans for particular bacterial coat markers, tumorcell antigens, mineral deposits, suspected toxins, hormone imbalancesf i lif l i i d h ifi d l lof genetic or lifestyle origin, and other specified molecules
- producing three-dimensional maps of desired targets withp g p gsubmillimeter spatial resolution.
- Treatment of various symptoms at the spot- Treatment of various symptoms at the spot
Microfluidics in a Chip with nanosurfaces
Biochip-IMB, Ltd.
A Dermal Display
A set of thousands of MassSpectrometers in one chip
Nanotechnology and BiosensorsNanotechnology and Biosensors
• Nanotechnology will contribute to a wide range of• Nanotechnology will contribute to a wide range of diagnostic applications through the development of:of:– Implantable Diagnostic Devices– Internal DiagnosticsInternal Diagnostics– Intracellular Diagnostics– Pathogen DetectionPathogen Detection
Bio-Sensors & ActuatorsIn-vivo Sensor
–Organic sensorWith telemetry–With telemetry
–100 microns–Biocompatible–Biodegradable
New Applications of Biosensors• Stent Monitor
– Restenosis– Pressure gradients– Plaque build-up– Artery thickening
h• Smart Catheter– Fibrillation Detection
• Post operative Patient Monitoring• Post-operative Patient Monitoring
• Drug DeliveryPill Imager
• Radiation Therapy– Dynamic Dose Control, – Micro-Targetingg g– Reconstruction Aid (angular uncertainty)
Nano BioSensors at the Hospital
• Enabling Technologies
NanowiresGE Global Research (2002)
• Enabling Technologies– Nanotubes & nanowires– Quantum dots– Hybrid organics/inorganic
• Benefits– Real time, in situ reading ofbiochemical activityHybrid organics/inorganic
materials – Cellular level optical imaging– Sensor guided precision surgical
tools
Nano BioSensors in the Doctor`s Office
100 nm100 nm
Self Assembled Block Copolymer Thin Films (GE Global Research, 2002)
100 nm100 nm
• Benefits– Total blood analysis in minutes– Rapid, accurate disease diagnosis
• Enabling Technologies– Molecular recognition
High density nano arrays p g– Patient specific disease treatment
– High density nano-arrays
Nano BioSensors at Home
I t t d H ll Eff tOrganic Light Emitting Diode (GE Global Research, 2002)
Integrated Hall Effect Sensor (GE Global Research, 1998)
• Enabling Technologies– Wireless communications– Self powered devices
• Benefits–Simple patient administered diagnostic tests
A t ti t i i f– Self powered devices– High resolution displays
–Automatic transmission ofoutpatient data from home tothe doctor
Percutaneous Monitoring with Miniature SensorsMiniature Sensors
• Digital plaster device checks vital signs such as:vital signs such as:– Temperature– Blood pressure– Glucose levelsGlucose levels
• Results via modem or PDA to a computer
• Out of range readings give alarmg g g• Based on hybrid analogue/digital
CMOS semiconductors
Device 3x5mm
Toumaz Technology
Systems Integration is Key to SuccessP i t f D i i A li ti
• In Vitro Analysis
P t i t ti fl t
Point of Decision Application
• Protein targeting fluorescent nanoparticles, Microfluidics Lab on a Chip,Nanowire & Nanocantilever sensorsNanocantilever sensors
• Medical Imaging
• MEMS, Nano SystemsMEMS, Nano Systems
• Communication Satellites
• 3D, Thin, Low Power Packaging
• Mobile Communications
Mi i Hi h P f MEMS b d k t lt d• Miniature, High Performance Systems
MEMS based pocket ultrasound system replacing stethoscope
Future Developments of Nanotechnology in Healthcarein Healthcare
• AFM as a nano-scalpel to dissect DNA from regions of a p gchromosome
• Nanoscale devices on catheter tips• Single cell diagnosisSingle cell diagnosis• Insertion of molecules into single cell using MEMS
devicesDr g deli er and monitoring de ices• Drug delivery and monitoring devices
• Biomedical lab testing at the point of care• Synthetic organs